As it happens i have an even better API than this article proposes!
They propose just using an async iterator of UInt8Array. I almost like this idea, but it's not quite all the way there.
They propose this:
type Stream<T> = {
next(): Promise<{ done, value: UInt8Array<T> }>
}
type Stream<T> = {
next(): { done, value: T } | Promise<{ done, value: T }>
}
- I can easily make mine from theirs
- In theirs the conceptual "stream" is defined by an iterator of iterators, meaning you need a for loop of for loops to step through it. In mine it's just one iterator and it can be consumed with one for loop.
- I'm not limited to having only streams of integers, they are
- My way, if I define a sync transform over a sync input, the whole iteration can be sync making it possible to get and use the result in sync functions. This is huge as otherwise you have to write all the code twice: once with sync iterator and for loops and once with async iterators and for await loops.
- The problem with thrashing Promises when splitting input up into words goes away. With async iterators, creating two words means creating two promises. With stream iterators if you have the data available there's no need for promises at all, you just yield it.
- Stream iterators can help you manage concurrency, which is a huge thing that async iterators cannot do. Async iterators can't do this because if they see a promise they will always wait for it. That's the same as saying "if there is any concurrency, it will always be eliminated."
> Obviously I'm gonna be biased, but I'm pretty sure my version is also objectively superior:
> - I can easily make mine from theirs
That... doesn't make it superior? On the contrary, theirs can't be easily made out of yours, except by either returning trivial 1-byte chunks, or by arbitrary buffering. So their proposal is a superior primitive.
On the whole, I/O-oriented iterators probably should return chunks of T, otherwise you get buffer bloat for free. The readv/writev were introduced for a reason, you know.
> So their proposal is a superior primitive.
This lines up with my thinking. The proposal should give us a building block in the form of the primitive. I would expect the grandparent comment’s API to be provided in a library built on top of a language level primitive.
How would you then deal with a stream of UTF8 code points? They won't fit in a UInt8Array. There will be too many for async iterators to perform well: you'll hit the promise thrashing issues discussed in the blog post
No, you'll just need to (potentially) keep the last 1-2 bytes of the previous chunk after each iteration. Come on, restartable UTF-8 APIs has been around for more than 30 years.
But those code points were just inputs to another stream transformation that turns a stream of code points into a stream of graphemes. Rapidly your advice turns into "just do everything in one giant transformation" and that loses the benefits of streams, which are meant to be highly composable to create efficient, multi-step transformation pipelines.
What's stopping you from implementing a stream transformation that reads the raw stream like a parser, outputting a grapheme or whatever unit you want only when it knows it's done reading it from the input?
No, it doesn't turn into this. Those two bytes of leftovers plus a flag are kept inside the stream generator that transforms bytes into code points, every time you pull it those two bytes are used as an initial accumulator in the fold that takes the chunk of bytes and yield chunk of code points and the updated accumulator. You don't need to inline it all into one giant transform.
Come on, it's how (mature libraries of) parser combinators work. The only slightly tricky part here is detecting leftover data in the pipeline.
To quote the article:
> If you want to stream arbitrary JavaScript values, use async iterables directly
OK, so we have to do this because code points are numbers larger than 8 bits, so they're arbitrary JS values and we have to use async iterables directly. This is where the amount of per-item overhead in an async iterable starts to strangle you because most of the actual work being done at that point is tearing down the call stack between each step of each iterator and then rebuilding it again so that the debugger has some kind of stack traces (if you're using for await of loops to consume the iterables that is).
As an abstraction I would say it does make mine superior that it captures everything theirs can and more that theirs can't.
Plus theirs involves the very concrete definition of an array, which might have 100 prototype methods in JS, each part of their API surface. I have one function in my API surface.
I did a microbenchmark recently and found that on node 24, awaiting a sync function is about 90 times slower than just calling it. If the function is trivial, which can often be the case.
If you go back a few versions, that number goes up to around 105x. I don’t recall now if I tested back to 14. There was an optimization to async handling in 16 that I recall breaking a few tests that depended on nextTick() behavior that stopped happening, such that the setup and execution steps started firing in the wrong order, due to a mock returning a number instead of a Promise.
I wonder if I still have that code somewhere…
> I did a microbenchmark recently and found that on node 24, awaiting a sync function is about 90 times slower than just calling it. If the function is trivial, which can often be the case.
I dabble in JS and… what?! Any idea why?
Any await runs the logic that attempts to release the main message pump to check for other tasks or incoming IO events. And it looks like that takes around 90 instructions to loop back around to running the next line of the code, when the process is running nothing else.
If you’re doing real work, 90 instructions ain’t much but it’s not free either. If you’ve got an async accumulator (eg, otel, Prometheus) that could be a cost you care about.
How did you come up with 90? Can you shed any might on the difference between the cost of promise resolution and the cost of await? Is there any cost component with how deep in the call stack you are when an await happens?
Essentially for loop of 10k iterations comparing `fn()` versus `await fn()` fed into a microbenchmark tool, with some fiddling to detect if elimination was happening or ordering was changing things.
I was bumping into PRs trying to eliminate awaits in long loops and thinking surely the overhead can’t be so high to warrant doing this, especially after node ~16. I was wrong.
Here is my test harness and results: https://github.com/conartist6/async-perf
I think the more generic stream concept is interesting, but their proposal is based on different underlying assumptions.
From what it looks like, they want their streams to be compatible with AsyncIterator so it'd fit into existing ecosystem of iterators.
And I believe the Uint8Array is there for matching OS streams as they tend to move batches of bytes without having knowledge about the data inside. It's probably not intended as an entirely new concept of a stream, but something that C/C++ or other language that can provide functionality for JS, can do underneath.
For example my personal pet project of a graph database written in C has observers/observables that are similar to the AsyncIterator streams (except one observable can be listened to by more than one observer) moving about batches of Uint8Array (or rather uint8_t* buffer with capacity/count), because it's one of the fastest and easiest thing to do in C.
It'd be a lot more work to use anything other than uint8_t* batches for streaming data. What I mean by that, is that any other protocol that is aware of the type information would be built on top of the streams, rather than being part of the stream protocol itself for this reason.
Yeah it makes sense to me that the actual network socket is going to move data around in buffers. I'm just offering an abstraction over that so that you can write code that is wholly agnostic to how data is stored.
And yes, because it's a new abstraction the compat story is interesting. We can easily wrap any source so we'll have loads of working sources. The fight will be getting official data sinks that support a new kind of stream
This is similar to how Clojure transducers are implemented: "give me the next thing plz." – https://clojure.org/reference/transducers
There is no such thing as Uint8Array<T>. Uint8Array is a primitive for a bunch of bytes, because that is what data is in a stream.
Adding types on top of that isn't a protocol concern but an application-level one.
> Adding types on top of that isn't a protocol concern but an application-level one.
I agree with this.
I have had to handle raw byte streams at lower levels for a lot of use-cases (usually optimization, or when developing libs for special purposes).
It is quite helpful to have the choice of how I handle the raw chunks of data that get queued up and out of the network layer to my application.
Maybe this is because I do everything from C++ to Javascript, but I feel like the abstractions of cleanly getting a stream of byte arrays is already so many steps away from actual network packet retrieval, serializing, and parsing that I am a bit baffled folks want to abstract this concern away even more than we already do.
I get it, we all have our focuses (and they're ever growing in Software these days), but maybe it's okay to still see some of the bits and bytes in our systems?
My concern isn't with how you write your network layer. Use buffers in there, of course.
But what if you just want to do a simple decoding transform to get a stream of Unicode code points from a steam of bytes? If your definition of a stream is that it has UInt8 values, that simply isn't possible. And there's still gonna be waaay too many code points to fall back to an async iterator of code points.
I think we're having a completely different conversation now. The parent comment I originally replied has been edited so much that I think the context of what I was referring to is now gone.
Also, I wasn't talking about building network layers, I was explicitly referring to things that use a network layer... That is, an application receiving streams of enumerable network data.
I also agree with what you're saying, we don't want UInt8, we want bits and bytes.
I'm really confused as to why the parent comment was edited so heavily. Oh well, that's social media for you.
A Uint8Array can be backed by buffers other than ArrayBuffer, which is where the types [0] come from.
[0] https://github.com/microsoft/TypeScript/blob/924810c077dd410...
I think the context that some other responders are missing is that in some functional languages, like Elixir, streams and iterators are used idiomatically to do staged transforms of data without necessitating accumulation at each step.
They are those languages versions of goroutines, and JavaScript doesn’t have one. Generators sort of, but people don’t use them much, and they don’t compose them with each other.
So if we are going to fix Streams, an implementation that is tuned only for IO-bound workflows at the expense of transform workflows would be a lost opportunity.
Other angles of critique & consideration already covered well by sibling commenters. One extra consideration (unrelated to streams, more general) is the API design & dev UX/DX:
type Stream<T> = {
next(): { done, value: T } | Promise<{ done, value: T }>
}
type Stream<T> = {
next(): { done, value: T }
}
type Stream<T> = {
next(): Promise<{ done, value: T }>
}
> My way, if I define a sync transform over a sync input, the whole iteration can be sync making it possible to get and use the result in sync functions. This is huge as otherwise you have to write all the code twice: once with sync iterator and for loops and once with async iterators and for await loops.
Writing all the code twice is cleaner in every implementation scenario I can envisage. It's very rare I want generalised flexibility on an API call - that leads to a lot of confusion & ambiguity when reading/reviewing code, & also when adding to/editing code. Any repetitiveness in handling both use-cases (separately) can easily be handled with well thought-out composition.
How is it cleaner? I used to actually do that. I wrote everything twice. I even built fancy tools to help me write everything twice.
But the bigger problem here is that sync and async aren't enough. You almost need to write everything three times: sync, async, and async-batched. And that async-batched code is gonna be gnarly and different from the other two copies and writing it in the first place and keeping it in sync is gonna give you headaches.
To see how it played out for me take a look at the difference between:
https://github.com/iter-tools/regex/blob/a35a0259bf288ccece2... https://github.com/iter-tools/regex/blob/a35a0259bf288ccece2... https://github.com/iter-tools/regex/blob/a35a0259bf288ccece2...
Your idea is flatten the UInt8Array into the stream.
While I understand the logic, that's a terrible idea.
* The overhead is massive. Now every 1KiB turns into 1024 objects. And terrible locality.
* Raw byte APIs...network, fs, etc fundamentally operate on byte arrays anyway.
In the most respectful way possible...this idea would only be appealing to someone who's not used to optimizing systems for efficiency.
JS engines actually are optimized to make that usage pattern fast.
Small, short-lived objects with known key ordering (monomorphism) are not a major cost in JS because the GC design is generational. The smallest, youngest generation of objects can be quickly collected with an incremental GC because the perf assumption is that most of the items in the youngest generation will be garbage. This allows collection to be optimized by first finding the live objects in the gen0 pool, copying them out, then throwing away the old gen0 pool memory and replacing it with a new chunk.
What happens when I send an extremely high throughput of data and the scheduler decides to pause garbage collection due to there being too many interrupts to my process sending network events? (a common way network data is handed off to an application in many linux distros)
Are there any concerns that the extra array overhead will make the application even more vulnerable to out of memory errors while it holds off on GC to process the big stream (or multiple streams)?
I am mostly curious, maybe this is not a problem for JS engines, but I have sometimes seen GC get paused on high throughput systems in GoLang, C#, and Java, which causes a lot of headaches.
Yeah I don't think that's generally a problem for JS engines because of the incremental garbage collector.
If you make all your memory usage patterns possible for the incremental collector to collect, you won't experience noticeable hangups because the incremental collector doesn't stop the world. This was already pretty important for JS since full collections would (do) show up as hiccups in the responsiveness of the UI.
Interesting, thanks for the info, I'll do some reading on what you're saying. I agree, you're right about JS having issues with hiccups in the UI due to scheduling on a single process thread.
Makes a lot of sense, cool that the garbage collector can run independently of the call stack and function scheduler.
It's not blazingly fast, no, but it's not as much overhead as people think either when they're imagining what it would cost to do the same thing with malloc. TC39 knew all this when they picked { step, done } as the API for iteration and they still picked it, so I'm not really introducing new risk but rather trusting that they knew what they were doing when they designed string iterators.
At the moment the consensus seems to be that these language features haven't been worth investing much in optimizing because they aren't widely used in perf-critical pathways. So there's a chicken and egg problem, but one that gives me some hope that these APIs will actually get faster as their usage becomes more common and important, which it should if we adopt one of these proposed solutions to the current DevX problems
I agree with your post, but in practice, couldn't you get back that efficiency by setting T = UInt8Array? That is, write your stream to send / receive arrays.
My reference point is from a noob experience with Golang - where I was losing a bunch of efficiency to channel overhead from sending millions of small items. Sending batches of ~1000 instead cut that down to a negligible amount. It is a little less ergonomic to work with (adding a nesting level to your loop).
How do you send multiple sub-streams in parallel?
There's one more interesting consequence: you rid yourself of the feedback problem.
To see the problem let's create a stream with feedback. Lets say we have an assembly line that produces muffins from ingredients, and the recipe says that every third muffin we produce must be mushed up and used as an ingredient for further muffins. This works OK until someone adds a final stage to the assembly line, which puts muffins in boxes of 12. Now the line gets completely stuck! It can't get a muffin to use on the start of the line because it hasn't made a full box of muffins yet, and it can't make a full box of muffins because it's starved for ingredients after 3.
If we're mandated to clump the items together we're implicitly assuming that there's no feedback, yet there's also no reason that feedback shouldn't be a first-class ability of streams.
In the language I've been working on for a couple months, Eidos, streams are achieved through iterators as well. It's dead simple. And lazy for loops are iterators, and there is piping syntax. This means you can do this (REPL code):
>> fn double(iter: $iterator<i32>) {
return *for x in iter { $yield( x * 2 )}
}
>> fn add_ten(iter: $iterator<i32>) {
return *for x in iter { $yield( x + 10 )}
}
>> fn print_all(iter: $iterator<i32>) {
for x in iter { $print( x )}
}
>> const source = *for x in [1, 2, 3] { $yield( x )}
>> source |> double |> add_ten |> print_all
12
14
16
Async iterables aren't necessarily a great solution either because of the exact same promise and stack switching overhead - it can be huge compared to sync iterables.
If you're dealing with small objects at the production side, like individual tag names, attributes, bindings, etc. during SSR., the natural thing to do is to just write() each string. But then you see that performance is terrible compared to sync iterables, and you face a choice:
1. Buffer to produce larger chunks and less stack switching. This is the exact same thing you need to do with Streams. or
2. Use sync iterables and forgo being able to support async components.
We faced this problem in Lit-SSR and our solution was to move to sync iterables that can contain thunks. If the producer needs to do something async it sends a thunk, and if the consumer receives a thunk it must call and await the thunk before getting the next value. If the consumer doesn't even support async values (like in a sync renderToString() context) then it can throw if it receives one.
This produced a 12-18x speedup in SSR benchmarks over components extracted from a real-world website.
I don't think a Streams API could adopt such a fragile contract (ie, you call next() too soon it will break), but having some kind of way where a consumer can pull as many values as possible in one microtask and then await only if an async value is encountered would be really valuable, IMO. Something like `write()` and `writeAsync()`.
The sad thing here is that generators are really the right shape for a lot of these streaming APIs that work over tree-like data, but generators are far too slow.
Yeah that problem you have is pretty much what I'm offering a solution to. It's the same thing you're already doing but more robust.
Also I'm curious why you say that generators are far too slow. Were you using async generators perhaps? Here's what I cooked up using sync generators: https://github.com/bablr-lang/stream-iterator/blob/trunk/lib...
This is the magic bit:
return step.value.then((value) => {
return this.next(value);
});You know now that I look at it I do think I need to change this code to defend better against multiple eager calls to `next()` when one of them returns a promise. With async generators there's a queue built in but since I'm using sync generators I need to build that defense myself before this solution is sound in the face of next();next(). That shouldn't be too hard though.
I liked conartist6's proposal,
type Stream<T> = {
next(): { done, value: T } | Promise<{ done, value: T }>
}
Engineers had a collective freak out panic back in 2013 over Do not unleash Zalgo, a worry about using callbacks with different activation patterns. Theres wisdom there, for callbacks especially; it's confusing if sometime the callback fires right away, sometimes is in fact async. https://blog.izs.me/2013/08/designing-apis-for-asynchrony/
And this sort of narrow specific control has been with us since. It's generally not cool to use MaybeAsync<T> = T | Promise<T>, for similar "it's better to be uniform" reasons. We've been so afraid of Zalgo for so long now.
That fear just seems so overblown and it feels like it hurts us so much that we can't do nice fast things. And go async when we need to.
Regarding the pulling multiple, it really depends doesn't it? It wouldn't be hard to make a utility function that lets you pull as many as you want queueing deferrables, allowing one at a time to flow. But I suspect at least some stream sources would be just fine yielding multiple results without waiting. They can internally wait for the previous promise, use that as a cursor.
I wasn't aware that generators were far too slow. It feels like we are using the main bit of the generator interface here, which is good enough.
Yeah I think people took away "It's better to be uniform" since they were trying to block out the memory of much-feared Zalgo, but if you read the article carefully it says in big letters "Avoid Synthetic Deferrals" then goes on to advocate for patterns exactly like MaybeAsync to be used "if the result is usually available right now, and performance matters a lot".
I was so sick of being slapped around by LJHarb who claimed to me again and again that TC39 was honoring the Zalgo post (by slapping synthetic deferrals on everything) that I actually got Isaacs to join the forum and set him straight: https://es.discourse.group/t/for-await-of/2452/5
That's an amazing thread, thanks for posting it! I've wanted `for await?()` for exactly these situations.
I feel like my deep dives into iterator performance are somewhat wasted because I might have made my project faster, but it's borderline dark magic and doesn't scale to the rest of the ecosystem because the language is broken.
> This pattern has caused connection pool exhaustion in Node.js applications using undici (the fetch() implementation built into Node.js), and similar issues have appeared in other runtimes.
That's an inherent flaw of garbage collected languages. Requiring to explicitly close a resource feels like writing C. Otherwise you have a memory leak or resource exhaustion, because the garbage collector may or may not free the resource. Even C++ is better at this, because it does reference counting instead.
The practical pain with Web Streams in Node.js is that they feel like they were designed for the browser use case first and backported to the server. Any time I need to process large files or pipe data between services, I end up fighting with the API instead of just getting work done.
The async iterable approach makes so much more sense because it composes naturally with for-await-of and plays well with the rest of the async/await ecosystem. The current Web Streams API has this weird impedance mismatch where you end up wrapping everything in transform streams just to apply a simple operation.
Node's original stream implementation had problems too, but at least `.pipe()` was intuitive. You could chain operations and reason about backpressure without reading a spec. The Web Streams spec feels like it was written by the kind of person who thinks the solution to a complex problem is always more abstraction.
It's news to me that anyone actually uses the web streams in node. I thought they were just for interoperability, for code that needs to run on both client and server.
You need to use them for things like Cloudflare and Denos HTTP servers, which is actually a fairly common (and nice) pattern:
A long time ago, I wrote an abstraction called a Repeater. Essentially, the idea behind it is, what would the Promise constructor look like if it was translated to async iterables.
import { Repeater } from "@repeaterjs/repeater";
const keys = new Repeater(async (push, stop) => {
const listener = (ev) => {
if (ev.key === "Escape") {
stop();
} else {
push(ev.key);
}
};
window.addEventListener("keyup", listener);
await stop;
window.removeEventListener("keyup", listener);
});
const konami = ["ArrowUp", "ArrowUp", "ArrowDown", "ArrowDown", "ArrowLeft", "ArrowRight", "ArrowLeft", "ArrowRight", "b", "a"];
(async function() {
let i = 0;
for await (const key of keys) {
if (key === konami[i]) {
i++;
} else {
i = 0;
}
if (i >= konami.length) {
console.log("KONAMI!!!");
break; // removes the keyup listener
}
}
})();
It’s one of those abstractions that’s feature complete and stable, and looking at NPM it’s apparently getting 6.5mil+ downloads a week for some reason.
Lately I’ve just taken the opposite view of the author, which is that we should just use streams, especially with how embedded they are in the `fetch` proposals and whatever. But the tee critique is devastating, so maybe the author is right. It’s exciting to see people are still thinking about this. I do think async iterables as the default abstraction is the way to go.
In the repeater callback, you're both calling the stop argument and awaiting it. Is it somehow both a function and a promise? Is this possible in JS?
edit: I found where stop is created[1]. I can't say I've seen this pattern before, and the traditionalist in me wants to dislike the API for contradicting conventions, but I'm wondering if this was designed carefully for ergonomic benefits that outweigh the cost of violating conventions. Or if this was just toy code to try out new patterns, which is totally legit also
[1]: https://github.com/repeaterjs/repeater/blob/638a53f2729f5197...
Yes, the callable promise abstraction is just a bit of effort:
let resolveRef;
const promise = new Promise((res) => { resolveRef = res; });
const callback = (data) => {
// Do work...
resolveRef(data); // This "triggers" the await
};
Object.assign(callback, promise);
Off topic - But just wanna say - Love the cheat code! 30 Lives added :-) Nostalgia runs deep with that code. So deep - in fact, that I sign many of my emails off with "Sent by hitting Up, Up, Down, Down, Left, Right, Left, Right, B, A"
Off topic to the off topic, but that logic doesn't look right. It seems like if up is pressed, you might need to reset i to 1 or 2, not 0.
Not accepting PRs for this. I think the logic is sound (Easter Eggs should be difficult to trigger).
Seems pretty similar to the design of OKIO in java [1]. With pretty similar goals ultimately. Here's a presentation on the internal details and design decisions. [2]
One minor niggle on freeing resources... I'm hoping it becomes more popular with libraries, but there's using/await using with disppse/disposeAsync which works similarly to C#'s use of using.
I'm working on a db driver that uses it by convention as part of connection/pool usage cleanup.
I like Node.JS streams. It's very satisfying to rent a 250MB memory machine and let it process GB's of data using streams.
Promises should not be a big overhead. If they are, that seems like a bug in JS engines.
At a native level (C++/rust), a Promise is just a closure added to a list of callbacks for the event loop. Yes, if you did 1 per streamed byte then it would be huge but if you're doing 1 promise per megabyte, (1000 per gig), it really shouldn't add up 1% of perf.
I'm fairly sure it's not Promises that are actually the heavy part but the `await` keyword as used in the `for await` loop. That's because await tries to preserve the call stack for debugging, making it a relatively high-level expensive construct from a perf perspective where a promise is a relatively low-level cheap one.
So if you're going to flatten everything into one stream then you can't have a for loop implementation that defensively awaits on every step, or else it'll be slooooooooow. That's my proposal for the change to the language is a syntax like
for await? (value of stream) {
}
the pull-stream module and its ecosystem is relevant here
the idea is basically just use functions. no classes and very little statefulness
There's a lot I like about this API, mainly the pull-based iterator approach. I don't really see what the value of the sync APIs are though. What's the difference of just using iterators directly for sync streams?
It avoids the overhead of Promises, so I can imagine that this would be quite useful if you know that blocking the thread is fine for a little while (e.g. in a worker).
I mean the APIs like `Stream.pullSync` you could do that with a regular (non-async) iterator/generator.
I really enjoyed reading this article however I can't help but feeling that if you need anything described within it probably shouldn't be writing JS in the first place
The Observables spec should just get merged and implemented.
Observables has moved to WHATWG [1] and been implemented in Chrome, although I don't know if the other browsers have expressed any interest (and there's still some issues [2] to be worked through).
But Observables really do not solve the problems being talked about in this post.
[1] https://github.com/WICG/observable [2] https://github.com/WICG/observable/issues/216
We deserve a better language than JavaScript.
Sadly it will never happen. WebAssembly failed to keep some of its promises here.
There's always a comment like this in most discussions about javascript.
> WebAssembly failed to keep some of its promises here
classic case of not using an await before your promise
Where can I find these not kept promises?
They haven't yet made languages other than JavaScript first-class languages for the web - https://hacks.mozilla.org/2026/02/making-webassembly-a-first.... I wouldn't call this a broken promise, but it was something people were hoping would take less than a decade.
As wonky as JS is I really like it. Typescript has done such a good job at making it fun to use.
Well, it's also possible to replace JavaScript with a better language, it's just too late for it...
It's a real shame that BYOB (bring your own buffer) reads are so complex and such a pain in the neck because for large reads they make a huge difference in terms of GC traffic (for allocating temporary buffers) and CPU time (for the copies).
In an ideal world you could just ask the host to stream 100MB of stuff into a byte array or slice of the wasm heap. Alas.
I wonder if you can get most of the benefit BYOB with a much simpler API:
for await (const chunk of stream) {
// process the chunk
stream.returnChunk(chunk);
}
(Lately I’ve been thinking that a really nice stream or receive API would return an object with a linear type so that you must consume it and possibly even return it. This would make it impossible to write code where task cancellation causes you to lose received data. Sadly, mainstream languages can’t do this directly.)
> The problems aren't bugs; they're consequences of design decisions that may have made sense a decade ago, but don't align with how JavaScript developers write code today.
> I'm not here to disparage the work that came before — I'm here to start a conversation about what can potentially come next.
Terrible LLM-slop style. Is Mr Snell letting an LLM write the article for him or has he just appropriated the style?
Heh, I was using emdashes and tricolons long before LLMs appropriated the style but I did let the agent handle some of the details on this. Honestly, it really is just easier sometimes... Especially for blogs posts like this when I've also got a book I'm writing, code to maintain etc. Use tools available to make life easier.
I think you'd be much better served by writing something rough that maintains your own voice!
I'm not sure any emdash use at all is what people are calling out typically(maybe it is?), more the sheer number of them typical in LLM written stuff.
Just ctrl-f'ing through previous public posts, I think there were a total of 7 used across about that many posts. This one for example had 57. I'm not good enough in proper English to know what the normal number is supposed to be, just pointing that out.
I found your article both interesting and readable.
It doesn't really matter what tools are used if the result is good
People are understandably a bit sensitized and sceptical after the last AI generated blog post (and code slop!) by Cloudflare blew up. Personally I'm fine with using AI to help write stuff as long as everything is proof-read and actually represents the authors thoughts. I would have opted to be a bit more careful and not use AI for a few blog posts after the last incident though if I was working at Cloudflare...
What was it specifically about the style that stood out as incongruous, or that hindered comprehension? What was it that made you stumble and start paying close attention to the style rather than to the message? I am looking at the two examples, and I can't see anything wrong with them, especially in the context of the article. They both employ the same rhetorical technique of antithesis, a juxtaposition of contrasting ideas. Surely people wrote like this before? Surely no-one complained?
The problem is less with the style itself and more that it's strongly associated with low-effort content which is going to waste the readers time. It would be nice to be able to give everything the benefit of the doubt, but humans have finite time and LLMs have infinite capacity for producing trite or inaccurate drivel, so readers end up reflexively using LLM tells as a litmus test for (lack of) quality in order to cut through the noise.
You might say well, it's on the Cloudflare blog so it must have some merit, but after the Matrix incident...
These AI signals will die out soon. The models are overusing actual human writing patterns, the humans are noticing and changing how they write, the models are updated, new patterns emerge, etc, etc. The best signal for the quality of writing will always be the source, even if they are "just" prompting the model. I think we can let one incident slide, but they are on notice.
> You might say well, it's on the Cloudflare blog so it must have some merit
I would instead say that it is written by James Snell, who is one of the central figures in the Node community; and therefore it must have some merit.
The idea is well articulated and comes across clear. What’s the issue? Taking a magnifying glass to the whole article to find sentence structure you think is “LLM-slop” is an odd way to dismiss the article entirely.
I’ve read my fair share of LLM slop. This doesn’t qualify.
cloudflare does seem to love ai written everything
You’ve got it backwards: LLMs were trained on human writing and appropriated our style.
Partially true. They've been trained and then aligned towards a preferred style. They don't use em-dashes because they are over-represented in the training material (majority of people don't use them).
It seems likely that with the written word, as with most things, a minority of people produce the majority of content. Most people publish relatively few words compared to professional writers.
Possibly the LLM vendors could bias the models more toward nonprofessional content, but then the quality and utility of the output would suffer. Skip the scientific articles and books, focus on rando internet comments, and you’ll end up with a lot more crap than you already get.
It might be a good idea to look into the research on streams as coalgebras, there is quite a bit, for example here https://cs.ru.nl/~jrot/CTC20/.
Coalgebras might seem too academic but so were monads at some point and now they are everywhere.
I tinkered with an alternative to stream interfaces:
https://github.com/ralusek/streamie
allows you to do things like
infiniteRecords
.map(item => doSomeAsyncThing(item), { concurrency: 5 });
infiniteRecords
.map(item => doSomeAsyncSingularThing(item), { concurrency: 5 })
.map(groupOf10 => doSomeBatchThing(groupsOf10), { batchSize: 10 })
// Can flatten back to single items
.map(item => backToSingleItem(item), { flatten: true });For gods sake, finally, somebody have said this!
Just use AsyncIterator<UIntArray>.
The objection is
> The Web streams spec requires promise creation at numerous points — often in hot paths and often invisible to users. Each read() call doesn't just return a promise; internally, the implementation creates additional promises for queue management, pull() coordination, and backpressure signaling.
But that's 95% manageable by altering buffer sizes.
And as for that last 5%....what are you doing with JS to begin with?
“ The Streams Standard was developed between 2014 and 2016 with an ambitious goal to provide "APIs for creating, composing, and consuming streams of data that map efficiently to low-level I/O primitives." Before Web streams, the web platform had no standard way to work with streaming data.”
This is what UDP is for. Everything actually has to be async all the way down and since it’s not, we’ll just completely reimplement the OS and network on top of itself and hey maybe when we’re done with that we can do it a third time to have the cloud of clouds.
The entire stack we’re using right down to the hardware is not fit for purpose and we’re burning our talent and money building these ever more brittle towering abstractions.
UDP is a protocol, not an API
True. But it’s also true that trying to shoehorn every use case into TCP streams is counter productive.
A stream API can layer over UDP as well (reading in order of arrival with packet level framing), but such a stream would a bit weird and incompatible with many stream consumers (e.g. [de]compression). A UDP API is simpler and more naturally event (packet) oriented. The concepts don’t mix well.
Still, it would be nice if they browser supported a UDP API instead of the weird and heavy DTLS and QUIC immitations.
TCP or UDP are orthogonal to this, so the original comment feels like a non sequitur. These streams are not network streams and could be a file, chunks of procedural audio, or whatever.
The browser does have a UDP data stream available for applications to send arbitrary bytes over UDP; it's part of WebRTC.
We're too busy building products while waiting for the perfect system to arrive.
I’m building everything from first principles, I’m not climbing the exponential curve with some billionaire that has to finance it.
I really doubt you are. you're not visiting the transistor shop every time you want to build a react component
Good thing your confidence is a soft requirement :)